Multiscale Modelling of Damage and Fracture Processes in Composite Materials

1. Front Matter

   Pages I-VII

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2. Modelling of anisotropic behavior in fiber and particle reinforced composites

   • Holm Altenbach

   Pages 1-62

3. Computational Mechanics of Failure in Composites at Multiple Scales

   • René de Borst

   Pages 63-101

4. Micromechanical modelling of strain hardening and tension softening in cementitious composites

   • B. L. Karihaloo

   Pages 103-135

5. Optimum Composite Laminates Least Prone to Delamination under Mechanical and Thermal Loads

   • B. L. Karihaloo

   Pages 137-170

6. Multiscale Computational Damage Modelling of Laminate Composites

   • Ladevèze Pierre

   Pages 171-212

7. Damage Modelling at Material Interfaces

   • Marcin Białas, Zenon Mróz

   Pages 213-270

8. Modelling of Damage and Fracture Processes of Ceramic Matrix Composites

   • Tomasz Sadowski

   Pages 271-309

Various types of composites are used in engineering practice. The most important are fibrous compositesy laminates and materials with a more complicated geometry of reinforcement in the form of short fibres and particles of various properties^ shapes and sizes. The aim of course was to understand the basic principles of damage growth and fracture processes in ceramic, polymer and metal matrix composites. Nowadays, it is widely recognized that important macroscopic properties like the macroscopic stiffness and strength, are governed by processes that occur at one to several scales below the level of observation. Understanding how these processes infiuence the reduction of stiffness and strength is essential for the analysis of existing and the design of improved composite materials. The study of how these various length scales can be linked together or taken into account simultaneously is particular attractive for composite materials, since they have a well-defined structure at the micro and meso-levels. Moreover, the microstructural and mesostructural levels are well-defined: the microstructural level can be associated with small particles or fibres, while the individual laminae can be indentified at the mesoscopic level. For this reason, advances in multiscale modelling and analysis made here, pertain directly to classes of materials which either have a range of relevant microstructural scales, such as metals, or do not have a very we- defined microstructure, e.g. cementitious composites. In particular, the fracture mechanics and optimization techniques for the design of polymer composite laminates against the delamination type of failure was discussed.

• behavior
• composite
• computational mechanics
• continuum mechanics
• damage
• engineering
• fracture
• linear optimization
• material
• materials
• mechanics
• mechanics of materials
• metal
• microstructure
• modeling

• Lublin University of Technology, Poland

  Tomasz Sadowski

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